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Preface

Project metadata

1. Working with Spring Stores

The goal of the Spring Content is to make it easy to create applications that manage content such as documents, images and video by significantly reducing the amount of boilerplate code that the Developer must create for themselves. Instead, the Developer provides interfaces only that declare the intent for the content-related functionality. Based on these, and on class-path dependencies, Spring Content is then able to inject storage-specific implementations.

Important

This chapter explains the core concepts and interfaces for Spring Content. The examples in this chapter use Java configuration and code samples for the Spring Content S3 module. Adapt the Java configuration and the types to be extended to the equivalents for the particular Spring Content module that you are using.

1.1. Core concepts

The central interfaces in the Spring Content are Store, AssociativeStore and ContentStore. These interfaces provide access to content streams through the standard Spring Resource API either directly or through association with Spring Data entities.

Example 1. ContentStore interface
public interface ContentStore<E, CID extends Serializable> {

	void setContent(E entity, InputStream content); 	(1)

	InputStream getContent(E entity);			(2)

	void unsetContent(E entity);				(3)
}

  1. Stores content and associates it with entity

  2. Returns the content associated with entity

  3. Deletes content and unassociates it from entity

For example, given an Entity User, a UserRepository and a ProfilePictureStore it is possible to associate and store a profile picture for each user.

Example 2. ContentStore interface
@Entity
@Data
public class User {
	@Id
	@GeneratedValue(strategy=GenerationType.AUTO)
	private Long id;

	private String username;

	@ContentId
	private String contentId;

	@ContentLength
	private Long contentLength
}

public interface UserRepository extends JpaRepository<User, Long> {
}

public interface ProfilePictureStore extends ContentStore<User, String> {
}

@SpringBootApplication
public class Application {
	public static void main(String[] args) {
		SpringApplication.run(Application.class, args);
	}

	@Bean
	public CommandLineRunner demo(UserRepository repository, ProfilePictureStore store) {
		return (args) -> {
			// create a new user
			User jbauer = new User("jbauer");

			// store profile picture
			store.setContent(jbauer, new FileInputStream("/tmp/jbauer.jpg"));

			// save the user
			repository.save(jbauer);
		};
	}
}

1.1.1. Using Stores with Multiple Spring Content Modules

Using a unique Spring Content module in your application keeps things simple, because all Store interfaces are bound to the one Spring Content module. Sometimes, applications require using more than one Spring Content module. In such cases, a store definition must distinguish between storage technologies by extending one of the module-specific ContentStore interfaces.

1.1.2. Events

Spring Content emits twelve events. Roughly speaking one for each Store method. They are:

  • BeforeGetResourceEvent

  • AfterGetResourceEvent

  • BeforeAssociateEvent

  • AfterAssociateEvent

  • BeforeUnassociateEvent

  • AfterUnassociateEvent

  • BeforeSetContent

  • AfterSetContent

  • BeforeGetContent

  • AfterGetContent

  • BeforeUnsetContent

  • AfterUnsetContent

Writing an ApplicationListener

If you wish to extend Spring Content’s functionality you can subclass the abstract class AbstractStoreEventListener and override the methods that you are interested in. When these events occur your handlers will be called.

There are two variants of each event handler. The first takes the entity with with the content is associated and is the source of the event. The second takes the event object. The latter can be useful, especially for events related to Store methods that return results to the caller.

Example 3. Entity-based AbstractContentRepositoryEventListener
public class ExampleEventListener extends AbstractContentRepositoryEventListener {

	@Override
	public void onAfterSetContent(Object entity) {
		...logic to inspect and handle the entity and it's content after it is stored
	}

	@Override
	public void onBeforeGetContent(BeforeGetContentEvent event) {
		...logic to inspect and handle the entity and it's content before it is fetched
	}
}

The down-side of this approach is that it does not filter events based on Entity.

Writing an Annotated StoreEventHandler

Another approach is to use an annotated handler, which does filter events based on Entity.

To declare a handler, create a POJO and annotate it as @StoreEventHandler. This tells Spring Content that this class needs to be inspected for handler methods. It iterates over the class’s methods and looks for annotations that correspond to the event. There are twelve handler annotations:

  • HandleBeforeGetResource

  • HandleAfterGetResource

  • HandleBeforeAssociate

  • HandleAfterAssociate

  • HandleBeforeUnassociate

  • HandleAfterUnassociate

  • HandleBeforeSetContent

  • HandleAfterSetContent

  • HandleBeforeGetContent

  • HandleAfterGetContent

  • HandleBeforeUnsetContent

  • HandleAfterUnsetContent

Example 4. Entity-based annotated event handler
@StoreEventHandler
public class ExampleAnnotatedEventListener {

	@HandleAfterSetContent
	public void handleAfterSetContent(SopDocument doc) {
		...type-safe handling logic for SopDocument's and their content after it is stored
	}

	@HandleBeforeGetContent
	public void onBeforeGetContent(Product product) {
		...type-safe handling logic for Product's and their content before it is fetched
	}
}

These handlers will be called only when the event originates from a matching entity.

As with the ApplicationListener event handler in some cases it is useful to handle the event. For example, when Store methods returns results to the caller.

Example 5. Event-based annotated event handler
@StoreEventHandler
public class ExampleAnnotatedEventListener {

	@HandleAfterSetContent
	public void handleAfterGetResource(AfterGetResourceEvent event) {
		SopDocument doc = event.getSource();
		Resource resourceToBeReturned = event.getResult();
		...code that manipulates the resource being returned...
	}
}

To register your event handler, either mark the class with one of Spring’s @Component stereotypes so it can be picked up by @SpringBootApplication or @ComponentScan. Or declare an instance of your annotated bean in your ApplicationContext.

Example 6. Handler registration
@Configuration
public class ContentStoreConfiguration {

	@Bean
	ExampeAnnotatedEventHandler exampleEventHandler() {
		return new ExampeAnnotatedEventHandler();
	}
}

1.1.3. Searchable Stores

Applications that handle documents and other media usually have search capabilities allowing relevant content to be found by looking inside of it for keywords or phrases, so called full-text search.

Spring Content is able to support this capability with it’s Searchable<CID> interface.

Example 7. Searchable interface
public interface Searchable<CID> {

    Iterable<T> search(String queryString);
}

Any Store interface can be made to extend Searchable<CID> in order to extend its capabilities to include the search(String queryString) method. For example:

public interface DocumentContentStore extends ContentStore<Document, UUID>, Searchable<UUID> {
}

...

@Autowired
private DocumentContentStore store;

Iterable<UUID> = store.search("to be or not to be");

For search to return actual results full-text indexing must be enabled. See Fulltext Indexing and Searching for more information on how to do this.

1.1.4. Renderable Stores

Applications that handle files and other media usually also have rendition capabilities allowing content to be transformed from one format to another.

Content stores can therefore optionally also be given rendition capabilities by extending the Renderable<E> interface.

Example 8. Renderable interface
public interface Renderable<E> {

	InputStream getRendition(E entity, String mimeType);
}

Returns a mimeType rendition of the content associated with entity.

Renditions must be enabled and renderers provided. See Renditions for more information on how to do this.

1.2. Creating Content Store Instances

To use these core concepts:

  1. Define a Spring Data entity and give it’s instances the ability to be associated with content by adding @ContentId and @ContentLength annotations

    @Entity
public class SopDocument {
	private @Id @GeneratedValue Long id;
	private String title;
	private String[] authors, keywords;

	// Spring Content managed attribute
	private @ContentId UUID contentId;
	private @ContentLength Long contentLen;
}

  2. Define an interface extending Spring Data’s CrudRepository and type it to the domain and ID classes.

    public interface SopDocumentRepository extends CrudRepository<SopDocument, Long> {
}

  3. Define another interface extending ContentStore and type it to the domain and @ContentId class.

    public interface SopDocumentContentStore extends ContentStore<SopDocument, UUID> {
}

  4. Optionally, make it extend Searchable

    public interface SopDocumentContentStore extends ContentStore<SopDocument, UUID>, Searchable<UUID> {
}

  5. Optionally, make it extend Renderable

    public interface SopDocumentContentStore extends ContentStore<SopDocument, UUID>, Renderable<SopDocument> {
}

  6. Set up Spring to create proxy instances for these two interfaces using JavaConfig:

    @EnableJpaRepositories
@EnableS3Stores
class Config {}
    Note
    		 The JPA and S3 namespaces are used in this example. If you are using the repository and content store abstractions for other databases and stores, you need to change this to the appropriate namespace declaration for your store module.

  7. Inject the repositories and use them

    @Component
public class SomeClass {
	@Autowired private SopDocumentRepository repo;
  	@Autowired private SopDocumentContentStore contentStore;

	public void doSomething() {

		SopDocument doc = new SopDocument();
		doc.setTitle("example");
		contentStore.setContent(doc, new ByteArrayInputStream("some interesting content".getBytes())); # (1)
		doc.save();
		...

		InputStream content = contentStore.getContent(sopDocument);
		...

		List<SopDocument> docs = doc.findAllByContentId(contentStore.findKeyword("interesting"));
		...

	}
}

    1. Spring Content will update the @ContentId and @ContentLength fields

1.3. Patterns of Content Association

Content can be associated with a Spring Data Entity in several ways.

1.3.1. Entity Association

The simplest, allowing you to associate one Entity with one Resource, is to decorate your Spring Data Entity with the Spring Content attributes.

The following example shows a Resource associated with an Entity Dvd.

@Entity
public class Dvd {
	private @Id @GeneratedValue Long id;
	private String title;

	// Spring Content managed attributes
	private @ContentId UUID contentId;
	private @ContentLength Long contentLen;

	...
}

public interface DvdRepository extends CrudRepository<Dvd, Long> {}

public interface DvdStore extends ContentStore<Dvd, UUID> {}

1.3.2. Property Association

Sometimes you might want to associate multiple different Resources with an Entity. To do this it is also possible to associate Resources with one or more Entity properties.

The following example shows two Resources associated with a Dvd entity. The first Resource is the Dvd’s cover Image and the second is the Dvd’s Stream.

@Entity
public class Dvd {
	private @Id @GeneratedValue Long id;
	private String title;

	@OneToOne(cascade = CascadeType.ALL)
	@JoinColumn(name = "image_id")
	private Image image;

	@OneToOne(cascade = CascadeType.ALL)
	@JoinColumn(name = "stream_id")
	private Stream stream;

	...
}

@Entity
public class Image {
	// Spring Data managed attribute
	private @Id @GeneratedValue Long id;

	@OneToOne
	private Dvd dvd;

	// Spring Content managed attributes
	private @ContentId UUID contentId;
	private @ContentLength Long contentLen;
}

@Entity
public class Stream {
	// Spring Data managed attribute
	private @Id @GeneratedValue Long id;

	@OneToOne
	private Dvd dvd;

	// Spring Content managed attributes
	private @ContentId UUID contentId;
	private @ContentLength Long contentLen;
}

public interface DvdRepository extends CrudRepository<Dvd, Long> {}

public interface ImageStore extends ContentStore<Image, UUID> {}

public interface StreamStore extends ContentStore<Stream, UUID> {}

Note how the Content attributes are placed on each property object of on the Entity itself.

When using JPA with a relational database these are typically (but not always) also Entity associations. However when using NoSQL databases like MongoDB that are capable of storing hierarchical data they are true property associations.

Property Collection Associations

In addition to associating many different types of Resource with a single Entity. It is also possible to associate one Entity with many Resources using a java.util.Collection property, as the following example shows.

@Entity
public class Dvd {
	private @Id @GeneratedValue Long id;
	private String title;

	@OneToMany
	@JoinColumn(name = "chapter_id")
	private List<Chapter> chapters;

	...
}

@Entity
public class Chapter {
	// Spring Data managed attribute
	private @Id @GeneratedValue Long id;

	// Spring Content managed attributes
	private @ContentId UUID contentId;
	private @ContentLength Long contentLen;
}

public interface DvdRepository extends CrudRepository<Dvd, Long> {}

public interface ChapterStore extends ContentStore<Chapter, UUID> {}

2. Filesystem Content Stores

2.1. Annotation-based Configuration

Spring Content Filesystem Stores are enabled with the following Java Config.

Example 9. Spring Content Filesystem Stores using Java Config
@Configuration
@EnableFilesystemStores
public static class ApplicationConfig {

    @Bean
    File filesystemRoot() {
        try {
            return Files.createTempDirectory("").toFile();
        } catch (IOException ioe) {}
        return null;
    }

    @Bean
    FileSystemResourceLoader fileSystemResourceLoader() {
        return new FileSystemResourceLoader(filesystemRoot().getAbsolutePath());
    }

}

By default content will be stored in a randomly chosen (at application startup) folder

2.2. Spring Boot Configuration

When using spring-content-fs-boot-starter (or content-fs-spring-boot-starter) the root for all file system stores will be a randomly chosen folder (at application start-up) under java.io.tmdir.

The following configuration properties (prefix spring.content.fs) are supported.

Property Description

filesystemRoot

The root location where file system stores place their content (defaults to java.io.tmpdir/<random>/).

2.3. Accessing Content

2.3.1. Storage Customization

By default, the Filesystem Store Module will store all content at the root of the backing store. Usually, this is sufficient.

However, for the cases where you need more control over the content in the backing store, the Module provides a placement service. This service can be configured through a standard Spring converter in a couple of different ways, depending on requirements.

Assume you have a Document entity like this:

@Entity
@Data
public class Document {

    @Id
    @GeneratedValue(strategy=AUTO)
    private Long id;

    @ContentId
    private UUID contentId;

    @ContentLength
    private Long contentLength;

    @MimeType
    private String mimeType;

    private String contentPath;
}

The first option is a converter that converts from the @ContentId type, in this case UUID, to String.

Example 10. Spring Content Filesystem Stores customizing storage customization by @ContentId type
@Configuration
public class FilesystemStoreConfiguration  {

   	public Converter<UUID,String> converter() {
		return new FilesystemStoreConverter<UUID,String>() {

			@Override
			public String convert(UUID source) {
				return String.format("/%s", source.toString().replaceAll("-", "/"));
			}
		};
	}

	@Bean
	public FilesystemStoreConfigurer configurer() {
		return new FilesystemStoreConfigurer() {

			@Override
			public void configureFilesystemStoreConverters(ConverterRegistry registry) {
				registry.addConverter(converter());
			}
		};
	}
}

This example uses a converter to generate a random location on disk based on the contentId

For example, a Document with a contentId of ec39f99b-5de3-4dc5-9753-a97c26f809c2 would be stored in the backing store at /ec39f99b/5de3/4dc5/9753/a97c26f809c2.

The second option is a converter that converts from the Entity type to String.

Example 11. Spring Content Filesystem Stores customizing storage customization by Entity type
@Configuration
public static class StoreConfig {
    @Bean
    public FilesystemStoreConfigurer configurer() {
        return new FilesystemStoreConfigurer() {

            @Override
            public void configureFilesystemStoreConverters(ConverterRegistry registry) {
                registry.addConverter(new Converter<Document, String>() {

                    @Override
                    public String convert(Document document) {
                        return document.getContentPath();
                    }
                });
            }
        };
    }

	@Bean
	public FilesystemStoreConfigurer configurer() {
		return new FilesystemStoreConfigurer() {

			@Override
			public void configureFilesystemStoreConverters(ConverterRegistry registry) {
				registry.addConverter(converter());
			}
		};
	}
}

This example allows the application to control the location in the backing store with a field on the entity.

For example, if you created a Document and set its contentPath to /path/to/my-file the content will be stored in the backing store at /path/to/my-file.

2.3.2. Setting Content

Storing content is achieved using the ContentStore.setContent(entity, InputStream) method.

If content has not yet been associated with this entity before and an ID has not been assigned by the application, one will be generated based on java.util.UUID and converted to the type of the @ContentId field.

The @ContentId and @ContentLength annotations will be updated on entity.

If content has been previously stored it will overwritten updating just the @ContentLength attribute, if appropriate.

2.3.3. Getting Content

Content can be accessed using the ContentStore.getContent(entity) method.

2.3.4. Unsetting Content

Content can be removed using the ContentStore.unsetContent(entity) method.

3.1. Overview

When enabled the Solr integration will forward all content to Solr for fulltext indexing which can then be searched by adding the optional Searchable<CID> interface to the Content Repositories.

3.2. Dependencies

Add the solrj to the classpath.

	<dependency>
		<groupId>org.apache.solr</groupId>
		<artifactId>solr-solrj</artifactId>
		<version>5.5.3</version>			(1)
		<exclusions>
			<exclusion>
				<groupId>org.codehaus.woodstox</groupId>
				<artifactId>wstx-asl</artifactId>
			</exclusion>
			<exclusion>
				<artifactId>log4j</artifactId>
				<groupId>log4j</groupId>
			</exclusion>
		</exclusions>
	</dependency>

  1. If using Spring Boot the version may be omitted

3.3. Enabling

  • Specify the @EnableFullTextSolrIndexing annotation to your @Configuration Spring Application block.

  • Ensure a (SolrJ) SolrClient @Bean is instantiated somewhere within your @Configuration Spring Application block.

3.4. Configuring

By default when the Solr module is enabled Spring-Content looks for a http://localhost:8983/solr/solr solr server with no username or password.

To change this behavior the following variables need to be set via the Externalized Configuration method.

Property Description

solr.url

Url of the Solr host (including port and core)

solr.username

Solr user

solr.password

Solr user’s password